System and/or method for reading, measuring and/or controlling intensity of light emitted from an LED

ABSTRACT

A system and/or a method for reads, measures and/or controls intensity of light emitted from a light-emitting diode (LED). The system and/or the method have a light intensity detector adjacent to the LED for reading and/or measuring the intensity of light emitted from the LED. The system and/or the method have a control circuit that may be electrically connected to both the detector and/or the LED for measuring and/or for controlling an intensity of light emitted from the LED. A housing surrounds the light detector and/or the LED. The housing has a pathway that allows only light emitted from the LED to reach the light detector. The LED has a finish and/or a coating that eliminates and/or retards absorption of light by internal components of the LED. The finish and/or the coating eliminates and/or retards reflection of the light by the LED.

BACKGROUND OF THE INVENTION

The present invention generally relates to a system and/or a method forreading, measuring and/or controlling intensity of light emitted from alight-emitting diode (LED). More specifically, the present inventionrelates to a system and/or a method that may prevent and/or may retardreflection of ambient light from a surface of the LED to allow anaccurate reading and/or an accurate measurement of the intensity oflight emitted from the LED. The system and/or the method may have alight detector located in a position adjacent to the LED for readingand/or measuring the intensity of light emitted from the LED. The systemand/or the method may have a control circuit that may be connected toboth the detector and the LED for measuring and/or controlling intensityof light emitted from the LED. A housing may surround the light detectorthat may have provide a pathway that may allow only light emitted fromthe LED to reach the light detector. The housing and the pathway maylimit and/or may prevent exposure of the light detector to ambient lightthat may not be emitted directly from the LED towards the lightdetector.

It is generally known that an LED is a semiconductor diode that has achip of semiconducting material doped with impurities to create a p-njunction. The semiconductor diode emits light when the same iselectrically biased in a forward direction of the p-n junction. Theemitted light may be, for example, infrared light, visible light and/ornear ultraviolet light. Further, the color of the emitted light variesdepending on the semiconducting material used. Additionally, optics areadded to the chip to shape a radiation pattern of the emitted light.

Further, it is generally known that an intensity of the emitted lightvaries over time. The intensity of the emitted light may be controlledby varying a voltage and/or a current of electricity applied to the LED.Therefore, control systems are provided to measure intensity of emittedlight and to control the voltage and/or the current applied to the LEDto produce a more stable intensity of emitted light over time.

However, the LED is often used in open systems where the LED may beexposed to ambient light. The ambient light may be emitted from lightsources external to the LED. The ambient light may be light emitted fromthe LED that has been reflected from a surface located adjacent to theLED. It is generally known that ambient light is absorbed and/orreflected by the LED and/or the semiconducting material. Absorption ofthe ambient light by the semiconducting material alters the propertiesof the semiconducting material and contributes to the varying intensityof emitted light. Moreover, ambient light is often passively detected bythe control systems. Therefore, known control systems measure intensityof emitted light and, inadvertently, ambient light to control thevoltage and/or the current applied to the LED. As a result, theintensity of light emitted from the LED used with known control systemsvaries substantially over time even when used in conjunction with knowncontrol systems designed to prevent the same.

A need, therefore, exists for a system and/or a method for reading,measuring and/or controlling intensity of light emitted from an LED.Additionally, a need exists for a system and/or a method that mayprevent and/or may retard reflection of ambient light from a surface ofthe LED to allow an accurate reading and/or an accurate measurement ofthe intensity of light emitted from the LED. Further, a need exists fora system and/or a method that may prevent absorption of ambient light bya semiconducting material of the LED to control intensity of lightemitted from the LED. Still further, a need exists for a light detectorthat may be exposed only to light emitted by the LED. Still further, aneed exists for a control circuit that may be electrically connected toboth the light detector and the LED for measuring and/or for controllingintensity of light emitted from the LED. Still further, a need existsfor a housing that may surround the light detector to limit exposure ofthe light detector to ambient light. Moreover, a need exists for apathway in the housing that may allow only light emitted from the LED toreach the light detector.

SUMMARY OF THE INVENTION

The present invention generally relates to a system and/or a method forreading, measuring and/or controlling intensity of light emitted from alight-emitting diode (LED). More specifically, the present inventionrelates to a system and/or a method that may prevent and/or may retardreflection of ambient light from an emitting surface of the LED to allowan accurate reading and/or an accurate measurement of the intensity oflight emitted from the LED.

An emitting surface of the LED may be modified to reduce reflection ofambient light from the emitting surface and/or to limit exposure ofinternal components of the LED to ambient light. The system and/or themethod may have a light detector located in a position adjacent to theLED for reading and/or measuring the intensity of light emitted from theLED. The system and/or the method may have a control circuit that may beelectrically connected to both the detector and the LED for measuringand/or controlling intensity of light emitted from the LED. The controlcircuit may monitor the intensity of the light emitted from the LED thatmay be read and/or measured by the light detector. As a result, thecontrol circuit, by way of a negative feedback loop mechanism, mayregulate a voltage and/or a current of electricity applied to the LED tocontrol the intensity of light emitted from the LED.

The system and/or the method may have a housing that may surround thelight detector. The housing may have a pathway that may allow only lightemitted from the LED to reach the light detector. An angle of thepathway relative to the LED and/or a location of the pathway relative toan illuminated environment within which the LED and/or the housing aresituated may limit and/or may prevent exposure of the light detector toambient light that may not be emitted directly from the LED towards thelight detector.

The LED and the light detector may both be located in a chamber designedto limit exposure of both the LED and the light detector to ambientlight. The chamber may have an aperture for allowing light emitted fromthe LED to exit the chamber to illuminate an environment in which thechamber is located. Further, the chamber may limit exposure of the LEDand/or the light detector to ambient light that may enter the chambervia the aperture.

The system and/or the method may have a surface to reflect light emittedfrom the LED away from the detector and/or to illuminate an environmentthat is not directly opposite from the emitting surface of the LED.

To this end, in an embodiment of the present invention, a system forcontrolling light emitted from a light source in an environment havingambient light is provided. The system has an LED to emit light whereinthe light emitted from the LED has an intensity wherein the LED has anemitting surface to transmit the light emitted from the LED wherein theemitting surface has a finish to reduce reflection of the ambient lightfrom the emitting surface. Further, the system has a detector adjacentto the LED to detect the intensity of the light emitted from the LED.Still further, the system has a control circuit for monitoring theintensity of the light detected by the detector wherein the controlcircuit is electrically connected to the detector and the LED whereinthe control circuit regulates the intensity of light emitted by the LED.Moreover, the system has a tower having an internal compartment thatsurrounds the detector wherein the tower prevents exposure of thedetector to the ambient light wherein the tower has an external surfaceand a pathway wherein the pathway is located between the detector insidethe internal compartment and the external surface for transmitting lightemitted from the LED to the detector in the compartment.

In an embodiment, the tower is constructed from an opaque material.

In an embodiment, the system has a channel in the tower that extendsfrom the internal compartment to the external surface of the tower.

In an embodiment, the system has a pipe that extends from the internalcompartment past the external surface of the tower to a positionadjacent to the emitting surface of the LED.

In an embodiment, the system has a mirror on the external surface of thetower that reflects the light emitted from the LED away from the tower.

In an embodiment, the system has a surface that is substantially flatwherein the tower and the LED are mounted to the surface wherein thesurface is a printed circuit board.

In an embodiment, the system has a power source electrically connectedto the control circuit wherein the power source provides power to theLED.

In an embodiment, the emitting surface is abraded to reduce reflectionof ambient light from the emitting surface.

In an embodiment, the system has a coating on the emitting surface thatreduces reflection of the ambient light from the emitting surface.

In another embodiment, a system for reading light emitted from a lightsource in an environment having ambient light is provided. The systemhas an LED to emit light wherein the light emitted from the LED has anintensity wherein the LED has an emitting surface having a finish toreduce reflection of light from the emitting surface. Further, thesystem has a first detector adjacent to the LED to detect the intensityof light emitted from the LED. Still further, the system has a chamberin the environment having an internal compartment that surrounds thefirst detector and the LED wherein the chamber has an aperture to allowtransmission of the light emitted from the LED out of the chamberwherein the aperture allows transmission of the ambient light into thechamber. Moreover, the system has means for preventing exposure of theLED and the first detector to the ambient light that is transmitted intothe chamber through the aperture wherein the means for preventing allowsthe light emitted from the LED to exit the chamber through the aperture.

In an embodiment, the system has a control circuit for monitoring theintensity of light detected by the detector wherein the control circuitis electrically connected to the first detector and the LED wherein thecontrol circuit regulates the intensity of light emitted from the LED.

In an embodiment, the system has a lens sized to fit into the aperturewherein the lens focuses the light emitted from the LED through theaperture to the environment wherein the lens focuses the ambient lightfrom the environment onto the means for preventing.

In an embodiment, the system has a surface located between the apertureand the first detector wherein the surface absorbs the ambient lightthat is transmitted through the aperture into the internal compartmentof the chamber.

In an embodiment, the system has a surface located between the apertureand the first detector wherein the surface reflects the ambient lightthat is transmitted through the aperture into the chamber through theaperture.

In an embodiment, the system has a second detector located in a positionoutside of the chamber to detect an intensity of the ambient light inthe environment outside of the chamber.

In another embodiment, a method for controlling light emitted from alight source in an environment having ambient light is provided. Themethod has the step of providing a first light intensity detector, anLED having an emitting surface to transmit light emitted from the LED, acontrol circuit and a housing wherein the housing is located in aposition adjacent to the LED wherein the first light intensity detectoris located in a position within the housing wherein the housing has apathway for allowing the light emitted directly from the LED to reachthe detector wherein the control circuit is electrically connected tothe detector and the LED. Further, the method has the step of detectingan intensity of the light emitted from the LED through the pathway ontothe detector. Moreover, the method has the step of adjusting theintensity of light emitted from the LED.

In an embodiment, the method has the step of modifying the emittingsurface of the LED to reduce reflection of the ambient light from theemitting surface.

In an embodiment, the method has the step of providing a second lightintensity detector located in a position outside of the housing whereinthe second light intensity detector measures intensity of the ambientlight.

In an embodiment, the method has the step of applying a coating to theemitting surface of the LED wherein the coating reduces reflection ofthe ambient light from the emitting surface.

In an embodiment, the method has the step of abrading the emittingsurface of the LED to reduce reflection of the ambient light from theemitting surface.

It is, therefore, an advantage of the present invention to provide asystem and/or a method for reading, measuring and/or controllingintensity of light emitted from an LED.

Another advantage of the present invention is to provide a system and/ora method for reading, measuring and/or controlling intensity of lightemitted from an LED that may allow an accurate reading and/or anaccurate measurement of the intensity of light emitted from the LED.

And, another advantage of the present invention is to provide a systemand/or a method for reading, measuring and/or controlling intensity oflight emitted from an LED that may have a light detector located in aposition adjacent to the LED for reading and/or measuring the intensityof light emitted from the LED.

Yet another advantage of the present invention is to provide a systemand/or a method for reading, measuring and/or controlling intensity oflight emitted from an LED that may have a control circuit that may beelectrically connected to both the detector and the LED for measuringand/or controlling intensity of light emitted from the LED.

A further advantage of the present invention is to provide a systemand/or a method for reading, measuring and/or controlling intensity oflight emitted from an LED that may have a housing that may surround thelight detector.

Moreover, an advantage of the present invention is to provide a systemand/or a method for reading, measuring and/or controlling intensity oflight emitted from an LED that may have a housing and a pathway that mayallow only light emitted from the LED to reach the light detector.

And, another advantage of the present invention is to provide a systemand/or a method for reading, measuring and/or controlling intensity oflight emitted from an LED that may limit and/or may prevent exposure ofthe light detector to ambient light that may not be emitted directlyfrom the LED towards the light detector.

Yet another advantage of the present invention is to provide a systemand/or a method for reading, measuring and/or controlling intensity oflight emitted from an LED that may prevent and/or may retard reflectionof ambient light from a surface of the LED to allow an accurate readingand/or an accurate measurement of the intensity of light emitted fromthe LED.

Another advantage of the present invention is to provide a system and/ora method for reading, measuring and/or controlling intensity of lightemitted from an LED that may prevent absorption of ambient light by asemiconducting material of the LED to better control intensity of lightemitted from the LED.

Yet another advantage of the present invention is to provide a systemand/or a method for reading, measuring and/or controlling intensity oflight emitted from an LED wherein an emitting surface of the LED retardsreflection of ambient light from the emitting surface and/or limitsexposure of internal components of the LED to ambient light.

A still further advantage of the present invention is to provide asystem and/or a method for reading, measuring and/or controllingintensity of light emitted from an LED wherein the light detector andthe LED may both be located in a chamber designed to limit exposure ofboth the LED and the light detector to ambient light.

Moreover, an advantage of the present invention is to provide a systemand/or a method for reading, measuring and/or controlling intensity oflight emitted from an LED that may have a chamber for the LED and alight detector that may have an aperture for allowing light emitted fromthe LED to exit the chamber to illuminate an environment in which thechamber is located.

And, another advantage of the present invention is to provide a systemand/or a method for reading, measuring and/or controlling intensity oflight emitted from an LED that may have a chamber for housing the LEDand a light detector that limits exposure of the LED and/or the lightdetector to ambient light that may enter the chamber via an aperture inthe chamber.

Yet another advantage of the present invention is to provide a systemand/or a method for reading, measuring and/or controlling intensity oflight emitted from an LED that may have a surface to reflect lightemitted from the LED away from a detector and/or to illuminate anenvironment that is not directly opposite from the emitting surface ofthe LED.

Moreover, an advantage of the present invention is to provide a systemand/or a method for reading, measuring and/or controlling intensity oflight emitted from an LED that may maintain a generally uniform and/orconstant intensity of light emitted from the LED.

And, another advantage of the present invention is to provide a systemand/or a method for reading, measuring and/or controlling intensity oflight emitted from an LED that may produce high resolution light.

Yet another advantage of the present invention is to provide a systemand/or a method for reading, measuring and/or controlling intensity oflight emitted from an LED that may have applications in smoke detectors,control systems for pneumatic cylinders, bar code scanning technologiesand/or the like.

Additional features and advantages of the present invention aredescribed in, and will be apparent from, the detailed description of thepresently preferred embodiments and from the drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates a top view of a system for reading, measuring and/orcontrolling intensity of light emitted from an LED in an embodiment ofthe present invention.

FIG. 2 illustrates a cross-sectional view taken generally along line I-Iof FIG. 1 of a system for reading, measuring and/or controllingintensity of light emitted from an LED in an embodiment of the presentinvention.

FIG. 3A illustrates a top view of a system for reading, measuring and/orcontrolling intensity of light emitted from an LED in an embodiment ofthe present invention.

FIG. 3B illustrates a cross-sectional view taken generally along lineIIIa-IIIa of FIG. 3A of a system for reading, measuring and/orcontrolling intensity of light emitted from an LED in an embodiment ofthe present invention.

FIG. 4 illustrates a top view of a system for reading, measuring and/orcontrolling intensity of light emitted from an LED in an embodiment ofthe present invention.

FIG. 5 illustrates a cross-sectional view taken generally along lineIV-IV of FIG. 4 of a system for reading, measuring and/or controllingintensity of light emitted from an LED in an embodiment of the presentinvention.

FIG. 6 illustrates a top view of a system for reading, measuring and/orcontrolling intensity of light emitted from an LED in an embodiment ofthe present invention.

FIG. 7 illustrates a cross-sectional view taken generally along lineVI-VI of FIG. 6 of a system for reading, measuring and/or controllingintensity of light emitted from an LED in an embodiment of the presentinvention.

FIG. 8 illustrates a top view of a system for reading, measuring and/orcontrolling intensity of light emitted from an LED in an embodiment ofthe present invention.

FIG. 9 illustrates a cross-sectional view taken generally along lineVIII-VIII of FIG. 8 of a system for reading, measuring and/orcontrolling intensity of light emitted from an LED in an embodiment ofthe present invention.

FIG. 10 illustrates a black box diagram of a system for reading,measuring and/or controlling intensity of light emitted from an LED inan embodiment of the present invention.

DETAILED DESCRIPTION OF THE PRESENTLY PREFERRED EMBODIMENTS

The present invention generally relates to a system and/or a method forreading, measuring and/or controlling intensity of light emitted from alight emitting diode (LED). More specifically, the present inventionrelates to a system and/or a method that may prevent and/or may retardreflection of ambient light from a surface of the LED to allow anaccurate reading and/or an accurate measurement of the intensity oflight emitted from the LED. The system and/or the method may have alight detector located in a position adjacent to the LED for readingand/or measuring the intensity of light emitted from the LED. The systemand/or the method may have a control circuit that may be electricallyconnected to both the detector and the LED for measuring and/orcontrolling intensity of light emitted from the LED. A tower maysurround the light detector. The tower may have a pathway that may allowonly light emitted from the LED to reach the light detector. The housingand the pathway may limit and/or may prevent exposure of the lightdetector to ambient light that may not be emitted directly from the LEDtowards the light detector.

Referring now to the drawings wherein like numerals refer to like parts,FIGS. 1, 2, 3A, 3B and 4-10 illustrate systems 20, 40, 60, 80, 100, 120and/or components of the systems 20, 40, 60, 80, 100, 120 for reading,measuring and/or controlling intensity of light emitted from an LED 2 inembodiments of the present invention. In an embodiment, the LED 2 mayhave optics for shaping a radiation pattern of the LED from an emittingsurface 3 of the LED 2. The LED 2 may emit one or more colors of light,for example, blue light, red light, green light, white light and/or thelike. The LED 2 may emit one or more types of light such as, forexample, infrared light, visible light, ultraviolet light and/or thelike. The present invention should not be deemed as limited to aspecific embodiment of the LED 2. It should be understood that the LED 2may be any LED as known to one having ordinary skill in the art.

In an embodiment, the emitting surface 3 of the LED 2 may have one ormore finishes 5 a and/or coatings 5 b that may absorb ambient lightand/or may prevent and/or may retard reflection of ambient light fromthe emitting surface 3 of the LED 2. The finishes 5 a and/or thecoatings 5 b may be, for example, matte finishes and/or coatings thatmay allow light to escape the emitting surface while preventing and/orretarding ambient light from entering and/or being reflected by theemitting surface 3. The finishes 5 a and/or the coatings 5 b mayeffectively absorb ambient light on the emitting surface 3 of the LED 2.The finishes 5 a and/or the coatings 5 b may be produced by mechanicallyabrading and/or chemically altering the emitting surface 3 of the LED 2.In an embodiment the finishes 5 a and/or the coatings 5 b may be one ormore filters and/or chemicals placed over the emitting surface 3 of theLED 2. The present invention should not be deemed as limited to aspecific embodiment of the finishes 5 a and/or the coatings 5 b. Itshould be understood that the finishes 5 a and/or coatings 5 b may beany finishes and/or coatings for absorbing ambient light and/orpreventing and/or retarding reflection of ambient light as known to onehaving ordinary skill in the art.

Further, FIGS. 1, 2, 3A, 3B and 4-10 generally illustrate a detector 4that may be, for example, a light intensity detector, a photodiode, aphototransistor and/or other like detector that may output a currentand/or a voltage as a function of light intensity detected. The detector4 may read and/or may measure an intensity of light emitted from the LED2. As shown in FIG. 10, the detector 4 may be electrically connected toa control circuit 122 with an electrical connection 8. The electricalconnection 8 may be any electrically conductive connection, such as, forexample, one or more wires, leads, solder joints and/or the like. Thepresent invention should not be deemed as limited to a specificembodiment of the detector 4. It should be understood that the detector4 may be any detector for reading and/or measuring light intensity asknown to one having ordinary skill in the art.

As shown in FIG. 10, the control circuit 122 may be electricallyconnected to the LED 2 with an electrical connection 10. The electricalconnection 10 may be any electrically conductive connection, such as,for example, one or more wires, leads, solder joints and/or the like.The control circuit 122 may be electrically connected to a power source124, such as, for example, a battery, an electrical grid and/or thelike. The control circuit 122 may provide power to the LED 2 and/or tothe detector 4. The control circuit 122 may be, for example, an analogcircuit, a digital circuit and/or the like. The control circuit 122 maydetermine an intensity of light 1 emitted from the LED 2 by monitoring avoltage and/or a current produced by the detector 4 in response to anabsorption of light 1 by the detector 4. The control circuit 122 mayinstantaneously change a voltage and/or a current applied to the LED 2to regulate the intensity of light 1 emitted from the LED 2. The controlcircuit 122 may be used to regulate the intensity of light 1 emittedfrom the LED to be substantially uniform and/or stable over a period oftime. The present invention should not be deemed as limited to aspecific embodiment of the control circuit 122. It should be understoodthat the control circuit 122 may be any control circuit for measuringlight intensity and/or regulating voltage and/or current applied to anLED as known to one having ordinary skill in the art.

FIGS. 1, 2, 3A, 3B, 5, 7 and 9 generally illustrate a surface 6. Thesurface 6 may be a platform for securing the LED 2, the detector 4and/or one or more components of the systems 20, 40, 60, 80, 100, 120.The surface 6 may be, for example, a printed circuit board, a plasticsurface, a metal surface and/or the like. The surface 6 may provideelectrical connections 8, 10 for the detector 4 and/or the LED 2,respectively. The surface 6 may be any surface capable of holding theLED 2, the detector 4 and/or one or more components of the systems 20,40, 60, 80, 100, 120. The surface 6 may be a surface of an environmentin which the systems 20, 40, 60, 60, 100, 120 may be situated. Thepresent invention should not be deemed as limited to a specificembodiment of the surface 6. It should be understood that the surface 6may be any surface as known to one having ordinary skill in the art.

In an embodiment as illustrated in FIGS. 1 and 2, the system 20 may havea tower 22. The tower 22 may have a perimeter 28 defining an externalsurface 29. Further, the tower 22 may have a height defined between atop end 30 and a bottom end 32. The bottom end 32 may be located in aposition generally opposite to the top end 30. In an embodiment, thetower 22 may be generally cylindrical. In an embodiment, the tower 22may be constructed from an opaque material, such as, for example, metal,plastic and/or the like. In an embodiment, the tower 22 may have acompartment 26 that may be located entirely within the perimeter 28 ofthe tower 22.

The detector 4 may be situated within the compartment 26. Thecompartment 26 may have a perimeter 34 that may surround the detector 4.Further, the compartment 26 may have a height defined between a top side36 and a bottom side 38 located in a position generally opposite to thetop side 36. The tower 22 and/or the compartment 26 may be a housing forholding the detector 4. The tower 22 and/or the compartment 26 mayprevent the detector 4 from being exposed to ambient light locatedoutside the perimeters 28, 34. Moreover, the tower 22 may be mountedupright on the surface 6. The present invention should not be deemed aslimited to a specific embodiment of the tower 22 and/or the compartment26. It should be understood that the tower 22 and/or the compartment 26may be any shape and/or material that may house the detector 4 as knownto one having ordinary skill in the art.

In an embodiment, the tower 22 and/or the compartment 26 may be milledfrom the opaque material. In another embodiment, the tower 22 and/or thecompartment 26 may be formed by drilling, melting, machining, extrudingand/or molding the opaque material.

As shown in FIGS. 1 and 2, the tower 22 may have a channel 24 that mayextend at an angle from the external surface 29 of the tower 22 to thecompartment 26. In an embodiment, the channel 24 may extend at the anglefrom the bottom end 32 of the tower 22 towards the top end 30 of thetower 22. As shown in FIGS. 1 and 2, the channel 24 may be tubular inshape and may have a diameter. The channel 24 may be sized to allow areadable amount of light 1 to reach the detector 4. The channel 24 maybe, for example, a drilled hole in the tower 22. In an embodiment, theLED 2 may be mounted upright on the surface 6 and may be situatedadjacent to the tower 22. The light 1 emitted from the emitting surface3 of the LED 2 may travel through the channel 24 and may be read and/ormeasured by the detector 4 situated in the compartment 26 of the tower22. The system 20 may be situated in an environment containing ambientlight emitted from the LED 2 and/or containing ambient light emittedand/or reflected from other sources. The angle of the channel 24 withrespect to the emitting surface 3 of LED 2 and/or the position of thetower 22 may reduce and/or may prevent exposure of the detector 4 toambient light via the channel 24. Further, one or more of the finishes 5a and/or the coatings 5 b of the emitting surface 3 of the LED 2 mayabsorb ambient light and/or may prevent and/or may retard reflection ofambient light into the channel 24. As a result, the detector 4 mayaccurately read and/or detect the intensity of the light 1 emitted bythe LED 2.

In an embodiment, as illustrated in FIGS. 3A and 3B, the system 40 mayhave a tower 42. The tower 42 may have a perimeter 48 defining anexternal surface 49. Further, the tower may have a height definedbetween a top end 50 and a bottom end 52 that may be located in aposition generally opposite to the top end 50. The tower 42 may have acompartment 46 that may be located entirely within the perimeter 48 ofthe tower 42.

The compartment 46 may have may have a height defined between a top side56 and a bottom side 58 that may be located in a position generallyopposite to the top side 56. The compartment 46 may have a perimeter 54.The detector 4 may be situated within the tower 42 and/or thecompartment 46. The tower 42, and/or the compartment 46 may prevent thedetector 4 from being exposed to ambient light located outside of theperimeters 48, 54. The present invention should not be deemed as limitedto a specific embodiment of the tower 42 and/or the compartment 46. Itshould be understood that the tower 42 and/or the compartment 46 may beany shape and/or material that may prevent exposure of the detector 4 toambient light as known to one having ordinary skill in the art.

As shown in FIGS. 3A and 3B, the tower 42 may have a tube 44 that mayextend at an angle from the compartment 46 of the tower 42 to a positionadjacent to and external to the tower 42. The tube 44 may have a lengthdefined between a first end 43 and a second end 45 that may be locatedin a position generally opposite to the second end. In an embodiment,the tube 44 may extend at an angle from the top end 50 of the tower 42towards the surface 6 and/or the LED 2. As shown in FIGS. 3A and 3B, thetube 44 may be tubular in shape and may have a diameter. The tube 44 maybe sized to allow a readable amount of light 1 to reach the detector 4.The tube 44 may be, for example, a pipe and/or other like member thatmay allow the light 1 to enter and/or leave the first end 43 and/or thesecond end 45. The tube 44 may prevent ambient light from entering thetube 44 between the first end 43 and the second end 45. In anembodiment, the LED 2 may be mounted upright on the surface 6 and may besituated adjacent to the tower 42. The light 1 emitted from the emittingsurface 3 of the LED 2 may travel through the tube 44 and may be readand/or measured by the detector 4 that may be situated in thecompartment 46 of the tower 42.

The system 40 may be situated in an environment containing ambient lightemitted from the LED 2 and/or containing ambient light emitted and/orreflected from other sources. The angle of the tube 44 with respect tothe emitting surface 3 of the LED 2 and/or the position of the tower 42may reduce and/or may prevent exposure of the detector 4 to ambientlight via the tube 44. Further, one or more of the finishes 5 a and/orthe coatings 5 b of the emitting surface 3 of the LED 2 may absorbambient light and/or may prevent and/or may retard reflection of ambientlight into the tube 44. As a result, the detector 4 may accurately readand/or detect the intensity of the light 1 emitted by the LED 2 throughthe tube 44.

In an embodiment, as illustrated in FIGS. 4 and 5, the system 60 mayhave a tower 62. The tower 62 may have a length defined between a backsurface 72 and a front surface 74 that may be located in a positiongenerally non-parallel to the back surface 72. The tower 62 may have awidth defined between a first end 68 and a second end 70 that may belocated in a position generally opposite to the first end 68. In anembodiment, a profile of the tower 62 may be generally triangular. In anembodiment, the front surface 74 may be a mirror and/or other likesurface capable of reflecting light. In an embodiment, the tower 62 mayhave a compartment 66 that may be located entirely between the frontsurface 74 and the back surface 72 and between the first end 68 and thesecond end 70 of the tower 62. The compartment 66 may have a perimeter67. The detector 4 may be situated within the tower 62 and/or thecompartment 66. The tower 62 and/or the compartment 66 may prevent thedetector 4 from being exposed to ambient light outside of the perimeter67. The present invention should not be deemed as limited to a specificembodiment of the tower 62 and/or the compartment 66. It should beunderstood that the tower 62 and/or the compartment 66 may be any shapeand/or material that may house the detector 4 as known to one havingordinary skill in the art. Moreover, the front surface 74 of the tower62 may be any surface capable of reflecting light as known to one havingordinary skill in the art.

As shown in FIGS. 4 and 5, the tower 62 may have a channel 64 that mayextend generally parallel to the surface 6 from the front surface 74 ofthe tower 62 to the compartment 66. As shown in FIGS. 4 and 5, thechannel 64 may be tubular in shape and may have a diameter. The channel64 may be sized to allow a readable amount of the light 1 to reach thedetector 4. The channel 64 may be, for example, a drilled hole in thetower 62. In an embodiment, the LED 2 may be mounted sideways on thesurface 6 and may be situated adjacent to the tower 62. The emittingsurface 3 of the LED 2 may be directed at the front surface 74 and/ormay be generally parallel to the back surface 72. The light 1 emittedfrom the emitting surface 3 of the LED 2 may travel through the channel64 and may be read and/or measured by the detector 4 that may besituated in the compartment 66 of the tower 62. Additional light 1emitted by the LED 2 may be reflected by the front surface 74 away fromthe tower 62 and/or the LED 2. An angle of reflection may depend on anangle of the front surface 74 with respect to the emitting surface 3 ofthe LED 2. In an embodiment, the angle of the front surface with respectto the emitting surface 3 may be, for example, forty-five (45) degreeswhich may reflect the additional light outward with respect to thesurface 6.

The system 60 may be situated in an environment containing ambient lightemitted from the LED 2 and/or containing ambient light emitted and/orreflected from other sources. A position of the LED 2 with respect tothe front surface 74 of the tower 62 may reduce and/or may preventexposure of the detector 4 to ambient light via the channel 64. Further,one or more of the finishes 5 a and/or the coatings 5 b of the emittingsurface 3 of the LED 2 may absorb ambient light and/or may preventand/or may retard reflection of ambient light into the channel 64. As aresult, the detector 4 may accurately read and/or detect the intensityof the light 1 emitted by the LED 2 through the channel 64.

In an embodiment, as illustrated in FIGS. 6 and 7, the system 80 mayhave a chamber 82. The chamber 82 may have a perimeter 84 defining anexternal surface 85. Further, the chamber 82 may have a height definedbetween a top end 96 and a bottom end 98 that may be located in aposition generally opposite to the top end 96. In an embodiment, thechamber 82 may be generally cylindrical. In an embodiment, the top end96 of the chamber 82 may have an aperture 99 for allowing ambient lightinto the chamber 82. The aperture 99 may be generally round. Inembodiment, the chamber 82 may have a lens 90 sized to fit inside andmay cover the aperture 99. The lens 90 may be, for example, a ball lens.The chamber 82 may have a compartment 86 that may be located entirelywithin the perimeter 84 of the chamber 82. The compartment 86 may have aperimeter 88 that may surround the detector 4 and one or more of theLEDs 2. The chamber 82 and/or the compartment 86 may be a housing forholding the detector 4, one or more LEDs 2 and/or a member 92. Themember 92 may extend from the surface 6 to a position between theaperture 99 and the bottom end 98 of the chamber 82. The member 92 mayhave a top surface 94 that may be substantially parallel to the aperture99 and/or the lens 90. The top surface 94 of the member 92 may bedesigned to absorb light and/or to reflect light entering the chamber 82through the lens 90. In an embodiment, the member 92 may be, forexample, a flathead screw that may be painted black. The chamber 82, thecompartment 86, the lens 99 and/or the member 92 may prevent thedetector 4 from being exposed to ambient light outside of the perimeters84, 88. Moreover, the chamber 82 and/or the LEDs 2 may be mountedupright on the surface 6. The present invention should not be deemed aslimited to a specific embodiment of the chamber 82, the compartment 86,the aperture 99, the lens 90 and/or the member 92. It should beunderstood that the chamber 82, the compartment 86, the aperture 99, thelens 90 and/or the member 92 may be any chamber, compartment, aperture,lens and/or member, respectively, as known to one having ordinary skillin the art.

As shown in FIGS. 6 and 7, the LEDs 2 may be mounted upright on thesurface 6 and may be situated adjacent to the perimeter 88 of thecompartment 86. The light 1 emitted from the emitting surface 3 of theLEDs 2 may travel and/or may be reflected around the chamber 82. Thelight 1 emitted from the emitting surface may be focused by the lens 90and may be transmitted outside of the chamber 82 to a focal pointoutside of the chamber 82. Further, the light 1 emitted from the LEDs 2may be read, measured and/or detected by the detector 4 situated in aposition adjacent to the LEDs within the compartment 86 of the chamber82.

The system 80 may be situated in an environment containing ambient lightemitted from the LEDs 2 and/or containing ambient light emitted and/orreflected from other sources. Ambient light outside of the chamber 82may be focused by the lens 90 onto the top surface 94 of the member 92.The top surface 94 of the member 92 may absorb the focused light and/ormay reflect the focused light towards the lens 90. Further, one or moreof the finishes 5 a and/or the coatings 5 b of the emitting surface 3 ofthe LEDs 2 may absorb excess ambient light and/or may prevent and/or mayretard reflection of excess ambient light in a direction towards thedetector 4. Further, the light 1 emitted from the LEDs 2 may be focusedby the lens 90 outside of the chamber 82 to illuminate the environment.In an embodiment, the system 80 may have an ambient light detector 81that may detect the intensity of ambient light in the environmentoutside of the chamber 82.

In an embodiment, as illustrated in FIGS. 8 and 9, the system 100 mayhave a chamber 102. The chamber 102 may have a perimeter 104 defining anexternal surface 105. Further, the chamber 102 may have a height definedbetween a top end 114 and a bottom end 116 that may be located in aposition generally opposite to the top end 114. In an embodiment, thetop end 114 of the chamber 102 may have a channel 110 to allow ambientlight into the chamber 102. In an embodiment, the channel 110 may begenerally tubular in shape.

In an embodiment, the chamber 102 may have a compartment 106 having aperimeter 108 that may be located entirely within the perimeter 104 ofthe chamber 102. The chamber 102 and/or the compartment 106 may be ahousing for holding the detector 4, the LED 2 and/or a member 112. Themember 112 may extend from the perimeter 108 of the compartment 106 to aposition between the channel 102 and the bottom end 116 of the chamber102. The member 112 may have a top surface 113 that may be substantiallyparallel to the top end 114 of the chamber 102. The top surface 113 ofthe member 112 may be designed to absorb light and/or to reflect lightentering the chamber 102 through the channel 110. The chamber 102, thecompartment 106, and/or the member 112 may prevent the detector 4 frombeing exposed to ambient light outside of the perimeters 104, 108. Thepresent invention should not be deemed as limited to a specificembodiment of the chamber 102, the compartment 106, the channel 110,and/or the member 112. It should be understood that the chamber 102, thecompartment 106, the channel 110 and/or the member 112 may be anychamber, compartment, channel and/or member, respectively, as known toone having ordinary skill in the art.

As shown in FIGS. 8 and 9, the LED 2 may be mounted upright on thesurface 6 and may be situated adjacent to the perimeter 108 of thecompartment 106. The light 1 emitted from the emitting surface 3 of theLED 2 may escape the chamber 102 through the channel 110. Further, thelight 1 emitted from the LED 2 may be read, measured and/or detected bythe detector 4 situated in a position adjacent to the LED within thecompartment 106 of the chamber 102.

Ambient light outside of the chamber 102 may enter the chamber 102. Thetop surface 113 of the member 112 may absorb the ambient light and/ormay reflect the ambient light towards and/or out of the chamber 102through the channel 110. Further, one or more of the finishes 5 a and/orthe coatings 5 b of the emitting surface 3 of the LED 2 may absorbexcess ambient light and/or may prevent and/or may retard reflection ofexcess ambient light in a direction towards the detector 4.

It should be understood that various changes and modifications to thepresently preferred embodiments described herein will be apparent tothose skilled in the art. Such changes and modifications may be madewithout departing from the spirit and scope of the present invention andwithout diminishing its attendant advantages. It is, therefore, intendedthat such changes and modifications be covered by the appended claims.

1. A system for controlling light emitted from a light source in anenvironment having ambient light, the system comprising: an LED to emitlight wherein the light emitted from the LED has an intensity whereinthe LED has an emitting surface to transmit the light emitted from theLED wherein the emitting surface has a finish to reduce reflection ofthe ambient light from the emitting surface; a detector adjacent to theLED to detect the intensity of the light emitted from the LED; a controlcircuit for monitoring the intensity of the light detected by thedetector wherein the control circuit is electrically connected to thedetector and the LED wherein the control circuit regulates the intensityof light emitted by the LED; and a tower having an internal compartmentthat surrounds the detector wherein the tower prevents exposure of thedetector to the ambient light wherein the tower has an external surfaceand a pathway wherein the pathway is located between the detector insidethe internal compartment and the external surface for transmitting lightemitted from the LED to the detector in the compartment.
 2. The systemof claim 1 wherein the tower is constructed from an opaque material. 3.The system of claim 1 further comprising: a channel in the tower thatextends from the internal compartment to the external surface of thetower.
 4. The system of claim 1 further comprising: a pipe that extendsfrom the internal compartment past the external surface of the tower toa position adjacent to the emitting surface of the LED.
 5. The system ofclaim 1 further comprising: a mirror on the external surface of thetower that reflects the light emitted from the LED away from the tower.6. The system of claim 1 further comprising: a surface that issubstantially flat wherein the tower and the LED are mounted to thesurface wherein the surface is a printed circuit board.
 7. The system ofclaim 1 further comprising: a power source electrically connected to thecontrol circuit wherein the power source provides power to the LED. 8.The system of claim 1 wherein the emitting surface is abraded to reducereflection of ambient light from the emitting surface.
 9. The system ofclaim 1 further comprising: a coating on the emitting surface thatreduces reflection of the ambient light from the emitting surface.
 10. Asystem for reading light emitted from a light source in an environmenthaving ambient light, the system comprising: an LED to emit lightwherein the light emitted from the LED has an intensity wherein the LEDhas an emitting surface having a finish to reduce reflection of lightfrom the emitting surface; a first detector adjacent to the LED todetect the intensity of light emitted from the LED; a chamber in theenvironment having an internal compartment that surrounds the firstdetector and the LED wherein the chamber has an aperture to allowtransmission of the light emitted from the LED out of the chamberwherein the aperture allows transmission of the ambient light into thechamber; and means for preventing exposure of the LED and the firstdetector to the ambient light that is transmitted into the chamberthrough the aperture wherein the means for preventing allows the lightemitted from the LED to exit the chamber through the aperture.
 11. Thesystem of claim 10 further comprising: a control circuit for monitoringthe intensity of light detected by the detector wherein the controlcircuit is electrically connected to the first detector and the LEDwherein the control circuit regulates the intensity of light emittedfrom the LED.
 12. The system of claim 10 further comprising: a lenssized to fit into the aperture wherein the lens focuses the lightemitted from the LED through the aperture to the environment wherein thelens focuses the ambient light from the environment onto the means forpreventing.
 13. The system of claim 10 further comprising: a surfacelocated between the aperture and the first detector wherein the surfaceabsorbs the ambient light that is transmitted through the aperture intothe internal compartment of the chamber.
 14. The system of claim 10further comprising: a surface located between the aperture and the firstdetector wherein the surface reflects the ambient light that istransmitted through the aperture into the chamber through the aperture.15. The system of claim 10 further comprising: a second detector locatedin a position outside of the chamber to detect an intensity of theambient light in the environment outside of the chamber.
 16. A methodfor controlling light emitted from a light source in an environmenthaving ambient light, the method comprising the steps of: providing afirst light intensity detector, an LED having an emitting surface totransmit light emitted from the LED, a control circuit and a housingwherein the housing is located in a position adjacent to the LED whereinthe first light intensity detector is located in a position within thehousing wherein the housing has a pathway for allowing the light emitteddirectly from the LED to reach the detector wherein the control circuitis electrically connected to the detector and the LED; detecting anintensity of the light emitted from the LED through the pathway onto thedetector; and adjusting the intensity of light emitted from the LED. 17.The method of claim 16 further comprising the step of: modifying theemitting surface of the LED to reduce reflection of the ambient lightfrom the emitting surface.
 18. The method of claim 16 further comprisingthe step of: providing a second light intensity detector located in aposition outside of the housing wherein the second light intensitydetector measures intensity of the ambient light.
 19. The method ofclaim 16 further comprising the step of: applying a coating to theemitting surface of the LED wherein the coating reduces reflection ofthe ambient light from the emitting surface.
 20. The method of claim 16further comprising the step of: abrading the emitting surface of the LEDto reduce reflection of the ambient light from the emitting surface.